Cell interaction with model membranes probing, modification and simulation of cell surface functions

Preparation and electrochemical behavior of gramicidin-bipolar lipid monolayer membranes supported on gold electrodes

Gramicidin-containing synthetic bolalipid membranes comprised of 2,2'-di-O-decyl-3,3'-O-1,20-eicosanyl-bis-rac-glycero-1,1'-diphosphocholine (C20BAS) have been synthesized and supported on gold electrodes. Supported membranes were prepared by first depositing a partial bolalipid layer on the electrode using a thioctic acid-modified bolalipid (1'-O-omega-thioctamidetetraethylene glycol-2,2'-di-O-decyl-3,3'-di-O-1,20-eicosanyl-bis-rac-glycero-1-phosphate, SSC20BAS) as an anchoring group, followed by a vesicle fusion step using either pure C20BAS or gramicidin-containing C20BAS (C20BAS-GA) vesicles. The latter configuration was designed to immobilize single, continuously-on channels of gramicidin in the C20BAS membrane. Vesicle deposition to form supported bolalipid monolayer membranes was monitored by impedance spectroscopy and cyclic voltammetry. Impedances were observed to increase with vesicle deposition time. Pretreatment of the impedance electrode with SSC20BAS accelerated the supported monolayer membrane deposition rate. Impedances decreased in a gramicidin concentration-dependent manner when gramicidin was incorporated into the C20BAS membrane. These supported bolalipid membranes are also surprisingly inert to organic solvent exposure (CH(3)CH(2)OH;CH(2)Cl(2)), suggesting that they may serve as robust host matrices for integral membrane protein-based sensors.

Comparison of the effects of dimyristoyl and soya phosphatidylcholine liposomes on human fibroblasts

The in vitro effects of prolonged exposure (8 days) of human skin fibroblasts to several concentrations of extruded dimyristoyl (dm-PC) and soya phosphatidylcholine (soya-PC) liposomes were compared. Prepared liposome suspensions were added to the fibroblast culture medium at phospholipid concentrations of 10, 50, 100, 200, and 300 microM. Survival curves and values of 50% inhibitory concentration (IC50) and area under the curve (AUC) were used to compare the response of the fibroblasts to the two types of liposomes. The effect of the incorporation of vitamin E in the liposomal preparations also was determined. Fibroblasts showed greater sensitivity toward the soya-PC liposomes (IC50 = 150 microM) than the dm-PC liposomes (IC50 = 212 microM). The presence of vitamin E in the soya-PC liposomes led to a 1.9-fold increase in the IC50, while dm-PC liposomes containing vitamin E showed an IC50 that was 1.1 times higher than that shown by control vitamin-free liposomes. Soya-PC liposomes containing vitamin E at a molar ratio of 10:0.5 (phospholipid:vitamin) were best tolerated by the fibroblasts (IC50 > 300 microM). It would appear that dm-PC liposomes are better tolerated by fibroblasts than those composed of soya-PC. However, the incorporation of vitamin E into the liposomes seems to reverse this effect, and it is the vitamin-containing soya-PC liposomes that are most compatible with the growth of fibroblasts in culture.

Receptor versus non-receptor mediated clearance of liposomes

Numerous studies have appeared over the years dealing with liposome-cell interaction mechanisms, most of them performed under in vitro conditions with isolated cell populations or cell lines. It is remarkable that, nonetheless, there hardly seem to exist established and generally accepted views on how precisely liposomes interact with cells and by what parameters this is influenced. In this article we will summarize and discuss the most relevant studies (in our opinion) on this matter in relation to in vivo conditions and with special attention to the relation between scavenger, complement and PS receptors.Researchers in the field have long been aware of the interaction of liposomes with blood proteins and their potential involvement in the process of liposome elimination from the blood circulation. A few of these 'opsonizing' proteins have been identified, but it is not clear to what extent each of them determines the fate of the liposome in the blood stream and how liposomal parameters such as size, charge and rigidity play a role in this process. We will include in this article our own recent observations on a thus far largely ignored class of such liposomal 'opsonins', the apolipoproteins. This class of plasma proteins, which physiologically are instrumental in hepatic lipoprotein clearance and processing, has been shown to contribute specifically to hepatocyte-mediated uptake of liposomes.Separately, as opposed to the fate of plain liposomes, we briefly touch on the clearance of surface-modified liposomes, which are designed to actively target specific cells or tissues. Plasma proteins are not usually supposed to play a significant role in the clearance of such liposomes. We will summarize these studies and address in this connection the question of how plasma proteins may interfere with such active targeting attempts.

Polyunsaturated fatty acid enrichment increases ultraviolet A-induced lipid peroxidation in NCTC 2544 human keratinocytes

The influence of cell enrichment with fatty acids with increasing degree of unsaturation on the ultraviolet A-induced formation of lipid-peroxidation products (thiobarbituric acid reactive substances [TBARS]) has been investigated in NCTC 2544 human keratinocytes. A 48-h preculture of cells in controlled medium supplemented with unsaturated fatty acids resulted in a marked increase in TBARS appearance under ultraviolet A exposure. This effect was dependent upon the degree of unsaturation of the fatty acids, with the following order of efficiency: arachidonic > linolenic > linoleic > oleic acid. For arachidonic acid (AA), the potentiating effect on ultraviolet A-induced lipid peroxidation was dependent upon the fatty acid concentration, with about a 2.5-fold increase in TBARS formation in cells pre-cultured with 5 x 10(-5) M AA, then exposed to a UVA dose of 13 J/cm2. The increase in TBARS formation by AA was almost totally prevented by supplementation of cells with 5 x 10(-5) M vitamin E, whereas buthionine sulfoximine, a chemical which depletes cell glutathione, potentiated lipid peroxidation. These results suggest that the nature of the fatty acids of cellular lipids could influence the response of keratinocytes to ultraviolet A, and especially the ultraviolet A-induced lipid peroxidation.

Inhibition of induced lymphocyte proliferation by lipid and protein components of the syncytiotrophoblast plasma membrane

PROBLEM

The aim of this work was to define the respective responsibilities of the lipid and protein components of syncytiotrophoblast plasma membranes on the inhibition of lymphocyte proliferation induced in vitro.

METHOD

A fractionation method using octyl-beta-D-glucopyranoside enabled lipoprotein, lipid, and protein fractions to be isolated from the membrane.

RESULTS

The lipid fraction was shown nonspecifically to inhibit lymphocyte proliferation, to a lower extent compared with the native membrane. Alternatively, the protein fraction used as a proteoliposome contained the totality of the cytostatic effect of the native fraction.

CONCLUSION

These results are discussed generally in the context of the immunoregulatory role of membrane lipids and proteins and in relation to the local properties of syncytiotrophoblast plasma membrane components in fetal graft tolerance.

Effects of incubation with liposomes at different temperatures on cultured melanoma cells (M14)

A melanoma cell line (M14) was used in order to investigate the effect of hyperthermia on the mechanisms of interaction between liposomes and cultured cells. The treatment was performed by adding different concentrations of multilamellar liposomes (L-alpha-dipalmitoylphosphatidylcholine, stearylamine and cholesterol in the ratio 7:2:1) to cell cultures which were then incubated at 37.0 or 41.5 degrees C for 2 h. The damage induced by liposome treatment in normothermia or hyperthermia was evaluated by determining cell survival and by electron microscopy. When different concentrations of liposomes were used, a dose-dependent impairment of cell survival was observed. An enhancement of the cytotoxic effect was observed when the treatment was performed at 41.5 degrees C. This effect went on even after 24 h from the end of the treatment, but the difference between cells treated in normothermia and hyperthermia was remarkably reduced. The mechanism of the liposome-plasma membrane interaction has been investigated by electron microscopy. Our observations demonstrated that the outer bilayer of the multilamellar liposomes was capable of fusing with the plasma membrane, inducing changes in its fluidity and molecular organization. Following this process the inner liposomal bilayers entered the cell. These effects seemed to be favoured when the treatment was performed under mild hyperthermic conditions, accounting for the synergic cytotoxic action displayed by the liposome-hyperthermia association.

Quantitative analysis of liposome-cell interactions in vitro: rate constants of binding and endocytosis with suspension and adherent J774 cells and human monocytes

We have characterized the parameters describing the total association (uptake) of liposomes with murine macrophage-like cell line J774 cells and human peripheral blood monocytes at 4 degrees C and at 37 degrees C with or without inhibitors of endocytosis. The uptake of neutral liposomes composed of phosphatidylcholine (PC)/cholesterol (Chol) (2:1 mole ratio) is about 10-fold lower than that of negatively charged liposomes composed of phosphatidylserine (PS)/PC/Chol (1:1:1). However, the rate of uptake of PC/Chol liposomes at 37 degrees C is still 10-fold higher than that by fluid-phase pinocytosis. The uptake of liposomes, which is mediated by high-affinity binding to the cell surface binding sites and subsequent endocytosis, could be simulated and predicted by model calculations employing mass action kinetics. The number of binding sites, affinity constants of binding at 37 degrees C and 4 degrees C, on- and off-rate constants of binding, and endocytic rate constants for both types of liposomes were determined. The number of binding sites and the binding constants for PS/PC/Chol liposomes binding to J774 cells is severalfold to an order of magnitude higher than that for PC/Chol liposomes, but the rate constants at which they are endocytosed following binding to the cells are similar for both liposome types. The binding of liposomes, especially PS/PC/Chol, to J774 cells and monocytes is greatly enhanced by adherence of cells to plastic substratum and is also increased by maturation/differentiation in the case of monocytes. Our quantitative analysis indicates that the binding and endocytosis of liposomes, especially PS-containing liposomes, is mediated by binding sites that have strong affinity, comparable to or about an order of magnitude smaller than other known particle-cell interactions with specific receptors such as virus and lipoproteins binding to cells.

Liposomal drug delivery to the eye and lungs: a preliminary electron microscopy study

Colloidal gold was used as an electron-dense marker for multilamellar vesicles to study the mechanism of liposome drug delivery to the eye and lung. A gold labelled multilamellar vesicle could be seen in the conjunctiva but there was no evidence of vesicles adsorbed to the epithelial surface of cornea or conjunctiva. In the lung, a free gold particle was isolated in type 1 epithelial cells and many vesicular structures were observed in the alveolar spaces which were not gold labelled. Experiments performed so far indicate that adsorption and not endocytosis was the major mechanism of uptake of drug or marker for multilamellar vesicles except for conjunctiva.

Evidence that the scavenger receptor is not involved in the uptake of negatively charged liposomes by cells

Scavenger receptors have a broad ligand specificity, ranging from modified low-density lipoproteins to a variety of high-molecular-weight poly-anions. A recent report by Nishikawa et al. (J. Biol. Chem. (1990) 265, 5226-5231) suggested that this receptor is also involved in the binding and endocytosis of liposomes containing negatively charged phospholipids. The mechanism by which liposomes are taken up by cells is of interest because liposomes are promising versatile carriers for macromolecules and drugs both in vitro and in vivo. In this report, we re-examine the role of the scavenger receptor in the uptake of liposomes using both Chinese hamster ovary cells transfected with the type I or type II bovine scavenger receptor, and smooth muscle cells induced to increase scavenger receptor expression by phorbol ester treatment. Expression of both types of scavenger receptors by Chinese hamster ovary cells induced an increase in the uptake of chemically modified low-density lipoproteins, but not the uptake of negatively charged liposomes. In smooth muscle cells treated with phorbol ester, scavenger receptor expression was upregulated and the uptake of chemically modified low-density lipoproteins was enhanced dramatically, but there was no effect on the uptake of negatively charged liposomes. We conclude that the existing evidence does not support the suggestion that the scavenger receptor is involved in the uptake of anionic liposomes by cells.

Increased binding of liposomes to cells by electric treatment

The influence of electric field treatments on the interaction of large unilamellar vesicles (liposomes) with animal cells was monitored by the fluorescence assay based on the use of the liposomes loaded by a dye 1-hydroxypyrene-1,3,6-trisulfonic acid (HPTS). It was shown that application of a short electric pulse (100 microseconds of 3-4 kV/cm) to the suspension of cells in presence of vesicles resulted in significant (more than 2 times) increase of the fluorescence associated with cells. The pH-sensitivity of the excitation spectrum of the dye and its interaction with the quencher were used to determine the nature of the phenomenon as the increase of the liposome binding onto the cell surface but not the consequence of a promotion of liposome uptake into the cells by endocytosis. The higher affinity for the liposome caused by the electric field has a lifetime of several minutes. The possible relation of the effect described to the electroporation of cell membranes and to macroscopic changes in membrane structure is discussed.

Low-density lipoproteins interact with liposome-binding sites on the cell surface

Under physiological conditions significant amounts of low-density lipoprotein LDL particles ar taken up by cells independently of specific high-affinity LDL receptors (apo-B receptors). Previously it was established that some cells contain surface sites capable of binding liposomes. We proposed that liposome-binding sites could contribute to LDL interaction with the cell surface via phospholipid molecules of LDL particles. To check this hypothesis we studied the competitive interaction of human LDL and DPPC liposomes with mouse embryo fibroblasts depleted of apo-B receptors by preliminary incubation with LDL. We have found that after removal of the liposome-binding sites from cell lamellae these areas of the cell surface lose their ability to bind LDL.

Modulation of the binding and endocytosis of concanavalin A by guinea pig keratinocytes: reversible antagonistic effects of cholesterol and phospholipid-liposomes

Alteration of guinea pig keratinocyte membrane microviscosities (eta) by liposomes of varying composition was determined by fluorescence polarization of 1,6-diphenyl-1,3,5-hexatriene. Measurements performed either with whole cell suspensions or Percoll-separated cell subpopulations, indicate a similar membrane microviscosity (eta = 3.37 poise +/- 10%) compared to those microviscosities reported for other cell types. Our findings show that treatment of guinea pig keratinocytes with liposomes composed of phospholipids results in a decreased membrane microviscosity (1.95 poise), whereas treatment of the cells with an emulsion of cholesterol hemisuccinate, or liposomes composed of cerebrosides, causes an increase in membrane microviscosity (3.85 poise and 5.55 poise +/- 10%, respectively). Changes in membrane fluidity had no significant effect on cell viability. A reduced membrane microviscosity resulted in a decrease in the binding of Concanavalin A to keratinocytes, whereas an increased microviscosity resulted in an increased binding of Concanavalin A. Furthermore, endocytosis of Concanavalin A bound to keratinocytes plasma membranes was not significantly affected by a reduced membrane microviscosity, whereas an increased membrane microviscosity completely blocked the endocytosis of Concanavalin A. Another novel observation was that membranes "fluidified" by phospholipid liposomes could be "rigidified" by treatment with cholesterol hemisuccinate and vice versa. Moreover, these alternate changes in membrane microviscosity resulted in simultaneous alternate changes in the binding of Concanavalin A to the keratinocyte surface.

Membrane effects of the polyene antibiotic amphotericin B and of some of its derivatives on lymphocytes

Amphotericin B (AmB) exhibits immunomodulating properties in mice. In vitro studies on lymphocytes, in relation with these properties, are reported here with AmB and two of its derivatives: the N-Fructosyl (N-Fru AmB) and the N-thiopropionyl (AmBSH) derivatives. Interactions of these molecules with thymocytes, a sensitive cell type, demonstrated that the extent of binding is not a toxicity parameter. In contrast, membrane fluidity changes have been observed and appeared to be related to toxicity. Experiments performed with normal B lymphocytes have shown that Amphotericin B derivatives were more potent polyclonal B cell activators than the parent compound. To go further in the understanding of these events, we have investigated in a B cell line WEHI 231, the changes in intracellular Ca2+ and membrane potential induced by AmB and AmBSH. The two polyenes were shown to induce membrane depolarization but no intracellular Ca2+ increase.

Interaction of amphotericin B and its N-fructosyl derivative with murine thymocytes: a comparative study using fluorescent membrane probes

The polyene antibiotics amphotericin B (AmB) and N-(1-deoxy-D-fructos-1-yl)amphotericin (N-Fru-AmB) have different activity towards murine thymocytes (N-Fru-AmB is less toxic but is a potent immunomodulator). The interactions of the drugs with these cells have been studied by fluorescence methods. Fluorescence energy transfer from 1-[4-(trimethylammonio) phenyl]-6-phenylhexa-1,3,5-triene, p-toluenesulfonate (TMA-DPH) to polyenes was used to follow the binding of the two drugs to the plasma membrane. The results, confirmed by circular dichroism measurements, indicate that at saturation the ratio AmB bound/plasma membrane lipid is low (less than 1 molecule of polyene for 170 lipids). The slightly higher binding of AmB as compared to N-Fru-AmB demonstrates that affinity of the antibiotic for plasma membrane does not account for the activity of the polyenes towards lymphocytes. The effect of the two polyenes on membrane fluidity was studied by steady-state fluorescence anisotropy. The results suggest that AmB strongly perturbs the structure of the membrane whereas only a slight decrease of the anisotropy is observed with N-Fru-AmB in the range of concentration where the biological activity has been demonstrated. Polyene location was further investigated by comparing the energy transfer efficiency obtained with TMA-DPH and with the parental compound 1,6-diphenylhexa-1,3,5-triene, p-toluene sulfonate (DPH). While AmB binds to plasma membrane, as well as to intracellular structures, N-Fru-AmB seems to accumulate into the cell and bind to intracellular membrane structures.

Fusion of lipid vesicles with ascites tumor cells and their lipid-depleted variants. Studies with radioactive- and fluorescent-labeled vesicles

Cultured ascites tumor cells and their lipid-depleted variants, which contained 35-40% less membrane phospholipid and cholesterol, were used for fusion experiments with unilamellar lipid vesicles which were between 300 and 600 nm in diameter. Vesicle-cell interaction was followed by tracer studies using vesicles double-labeled in the lipid moiety, by vesicle-encapsulated [3H] dextran, and by measurements of energy transfer between N-(10-[1-pyrene]decanoyl)sphingomyelin-labeled vesicles and alpha-parinaric acid-labeled cells in the presence of poly(ethylene glycol) (PEG) as fusogen. The reaction rates measured with the radiolabeled vesicles were found to follow patterns similar to those obtained with the resonance energy transfer assay. This latter method revealed a vesicle-cell membrane fusion reaction, which was substantiated by radiolabeling the internal cellular compartment after treatment of the cells with [3H]dextran-encapsulated vesicles as shown by electron microscopic autoradiography on semi-thin sections. Endocytosis as a reaction mechanism can be excluded, since no energy transfer was observed at 25 degrees C in the absence of PEG. Investigations of vesicle bilayer order and fluidity on vesicle-cell interaction revealed optimal reactivity, with intermediate fluidity corresponding to cholesterol/phospholipid ratios between 0.7 and 1.0 and fluorescence depolarization (P) values of 0.18 and 0.21. Lipid depletion decreased the reaction velocity between cells and vesicles by about 20%, exhibiting V values of 33.2 mumol/min, as compared to the control of 41.4 mumol/min determined for 10(7) cells. The affinity constants for vesicle lipid were affected only slightly with Km values of 0.195 mM (0.210 mM). The activation energies for the reaction were calculated to give values of EA = 22.44 kJ/mol for the control and of EA = 20.4 kJ/mol for the modified cells. These data indicate that the decrease in membrane lipid content apparently has no major influence on the extent of the interaction.

Correlation between the synergistic effect of liposomes and endotoxins on the activation of macrophage tumoricidal activity and the effect of liposomes on the rough endoplasmic reticulum of macrophages

Treatment of resident peritoneal macrophages of rats with small unilamellar vesicles of dipalmitoylphosphatidylcholine (DPPC SUV) potentiated their activation for tumor cell lysis by endotoxins. The fluorescence polarization of diphenylhexatriene (DPH) embedded in rough endoplasmic reticulum membranes isolated from DPPC SUV-treated macrophages was enhanced. The average fluorescence lifetime of DPH and the rotational correlation time deduced from anisotropy decay were unchanged, whereas the residual anisotropy and hence the order parameter were increased. The measurement of the fluorescence anisotropy of DPH as a function of the temperature showed a phase transition. No phase transition was observed in the rough endoplasmic reticulum membranes of macrophages either treated or not treated with cholesterol/DPPC SUV (1/1; mol/mol). The synergistic effect of DPPC SUV on the tumoricidal activity of macrophages induced by endotoxins appears to be correlated with the changes in the properties of the rough endoplasmic reticulum membranes. Both effects were transient; they had the same kinetics of induction and reversion, and they were both inhibited by cholesterol.

Lymphoma-vesicle interactions: vesicle adsorption, membrane fragmentation, and intermembrane protein transfer

Sonicated dimyristoylphosphatidylcholine vesicles interact with cultured murine lymphoma (BL/VL3) to generate complexes of vesicle and cell membrane components. Cell-free supernatants harvested after cell-vesicle incubations contain three distinct lipid species that can be separated by density gradient centrifugation. Analysis of protein and lipid composition and assays for cell and vesicle lumen contents reveal that the densest of the three lipid species comprises sealed plasma membrane fragments complexed with vesicles, while the least dense species is indistinguishable from pure phospholipid vesicles. The third, intermediate density species consists of topologically intact vesicles with associated plasma membrane proteins but without detectable cell lipids or cytoplasmic components. The membrane fragmentation and cell-to-vesicle protein transfer observed during lymphoma-vesicle incubations are examined as functions of cell and vesicle concentrations and incubation time.

Tissue specific opsonins for phagocytic cells and their different affinity for cholesterol-rich liposomes

In accordance with the finding of our in vivo experiments reported earlier [(1983) Biochim. Biophys. Acta 761, 142-157; (1986) Biochim. Biophys. Acta 888, 184-190], the results of in vitro experiments show that Kupffer cells avidly take up cholesterol-poor but not cholesterol-rich liposomes, whereas splenic phagocytic cells take up preferentially cholesterol-rich rather than cholesterol-poor liposomes in the presence of serum. Evidence presented here suggests that serum contains opsonins specific for hepatic and splenic phagocytic cells and these opsonins have different affinities for cholesterol-rich and cholesterol-poor liposomes.

Two pools of cholesterol in acetylcholine receptor-rich membranes from Torpedo

The acetylcholine receptor (AChR)-containing electroplax membranes from Torpedo californica have a relatively high cholesterol content. Reconstitution studies suggest that this cholesterol may be important in preserving or modulating the function of the acetylcholine receptor-channel complex. We have manipulated cholesterol levels in intact Torpedo AChR-rich membrane fragments using small, unilamellar phosphatidylcholine liposomes. Conditions have been established that allow further subfractionation of sucrose gradient purified Torpedo electroplax membranes into AChR-rich and ATPase-rich populations and that, at the same time, achieve cholesterol depletion without phospholipid back exchange or fusion. The incubation of membranes with excess liposomes could only achieve about a 50% reduction in the molar ratio of cholesterol to phospholipid. In no case was the number of cholesterol molecules per AChR oligomer reduced below 36. The remaining cholesterol could not be depleted either by longer incubations or by multiple, sequential depletions. Cholesterol depletion was accompanied by a significant increase in bulk membrane fluidity as measured by electron spin resonance spectroscopy, but the equilibrium binding parameters of acetylcholine to its receptor were unaltered. This suggests strongly that there exist two pools of cholesterol in the AChR-rich Torpedo electroplax membrane: an easily depleted fraction that influences bulk fluidity, and a tightly-bound fraction perhaps surrounding the AChR oligomer.

Liposome-cell interactions: in vitro discrimination of uptake mechanism and in vivo targeting strategies to mononuclear phagocytes

The interactions of liposomes with cells have been extensively studied to determine their potential use as vehicles for the delivery of drugs in vivo. Since intravenously administered liposomes are, for the most part, cleared by cells of the reticuloendothelial system (RES), considerable effort has been made to take advantage of this phenomenon rather than view it as an obstacle. Indeed, cells of the RES, in particular macrophages, have been shown to play a vital role in homeostasis and in host defence mechanisms against infection and neoplasia. In this article, we present an overview of liposome-cell interactions, with particular emphasis on the techniques used to monitor the interaction of liposomes with macrophages. Specifically, we discuss methodologies which can be used to differentiate between liposome-cell fusion, adsorption and endocytosis in vitro. In addition, we outline the various strategies that have been employed for both actively and passively targeting liposomes to macrophages in vivo. We also review the rationale and various techniques for designing liposomes for enhanced macrophage uptake, which, in certain cases, results in the selective release of liposome-entrapped compounds in situ.

Model membranes bearing glycolipids and glycoproteins

The forces that hold cell membrane components together are non-covalent and thermodynamically favoured in aqueous media. Hence virtually any glycolipid or membrane glycoprotein might be expected to be incorporable into lipid bilayer membranes and this expectation has been borne out. In addition methods have been developed for linking lipid fragments to species that would not otherwise be expected to associate with bilayers. Techniques that have been successfully used to generate bilayer structures bearing glycolipids and glycoproteins include hydration of films dried down from non-aqueous solutions of the components, detergent removal from aqueous component solutions, exogenous addition to preformed membranes, and various organic solvent injection or reverse phase approaches. Bilayer association of glycolipids and membrane glycoproteins, with preservation of specific receptor function, seem easy to achieve--in fact difficult not to achieve. Optimization of receptor function to accurately mimic that of cell membranes and efficient preservation of functions such as transport or second messenger activation, are typically more demanding, although still feasible. A systematic approach can give considerable insight into the processes involved via identification of minimal necessary factors. Unfortunately, the actual relative arrangement of components, so critical to subtleties of glycolipid and glycoprotein function, remains almost totally unknown for lack of morphological information in the size range of individual macromolecules. The latter problem has come to be the most critical limitation to many studies.

Modification of HT 29 cell response to the vasoactive intestinal peptide (VIP) by membrane fluidization

We used liposomes made with phospholipids of fatty acid chain length ranging from C12:0 to C16:0 to modify the cAMP dependent protein kinase (PK) activity of HT 29 cells induced by VIP or forskolin. Both VIP and forskolin effects were inhibited in dilauroylphosphatidylcholine (DLPC) treated cells. PK activity was slightly lowered when cells were treated by dimyristoylphosphatidylcholine (DMPC) liposomes. However neither VIP nor forskolin-induced PK activities were affected with dipalmitoylphosphatidylcholine (DPPC) liposomes. Furthermore, the binding of [125I]VIP to DLPC treated cells was drastically lowered whereas no change was observed when cells were incubated with DMPC or DPPC liposomes. On the other hand, the interaction of HT 29 cells with DLPC vesicles provoked a decrease in membrane cholesterol content with subsequent increase in membrane fluidity. These findings provide evidence that, in HT 29 cells, the mechanisms of VIP-receptor interaction and of adenylate cyclase activation is lipid dependent and is regulated by membrane fluidity.

Binding of macrophages and phospholipid flip-flop in supported lipid bilayers

Subclass-specific antibody-dependent interactions (binding and triggering) between macrophages and supported lipid bilayers have been studied. Percentages of mouse macrophage binding (J774 cell line) to the lipid bilayers were dependent on mouse monoclonal IgG subclasses. The efficiencies were as follows: IgG1 = IgG2a greater than IgG2b greater than IgG3. Furthermore, macrophage triggering (spreading) was more efficient on IgG2a- or IgG1-coated lipid bilayers than on IgG2a, IgG3, or non-specific rabbit IgG. The present experiments show also that phospholipid molecules are able to flip-flop from one side of a supported planar bilayer membrane to the other with a half-life of 10 h-1 day at 25 degrees C.

Selected positions of acyl chains are affected differently by antibody binding which results in decreased membrane fluidity

We have studied the interaction between monoclonal anti-trinitrophenyl antibodies (IgGl and IgG2a) and haptenated phospholipid vesicles using stopped-flow fluorometry. Conformational changes of the antibodies were induced very rapidly (within 0.1 s) after binding to lipid haptens (TNP-Cap-DPPE) on the membrane surfaces. Conversely, after that, the bound antibody molecules decreased the degree of molecular motion at different depths in the bilayer, ranging from the polar head group to the terminal methyl groups of the fatty acyl chains. Such an effect reaches all places of the bilayer within 40 s at 25 degrees C.

Subclass-specific antibody-dependent binding of macrophages to supported planar lipid monolayer membranes

Subclass-specific antibody-dependent binding of macrophages to supported planar lipid monolayers has been studied. The binding of the P388D1 macrophage-like cell line to planar DMPC or DPPC monolayers was dependent on IgC subclasses and hapten concentrations. The binding efficiencies were as follows on both 'solid' and 'fluid' lipid monolayer membranes; IgG1 = IgG2a greater than IgG2b greater than IgG3 = IgA. These results suggest that the present system is very useful for studying the mechanisms of the transmembrane signal triggered by Fc receptors of macrophages.

Targeting of liposomes containing methotrexate towards Tetrahymena pyriformis cells

The uptake of liposomes containing methotrexate by Tetrahymena pyriformis cells was investigated with the aim of producing liposome-cell association enabling methotrexate to be introduced into the cytoplasm of intact cells. Incubation of liposomes containing methotrexate with tetrahymena pyriformis cells resulted in a time and concentration-dependent uptake of entrapped methotrexate by the cells. The uptake by Tetrahymena pyriformis cells (at 1 hr) of liposomes prepared by phospholipids and gangliosides extracted from Tetrahymena pyriformis cells was approximately three fold higher than that of liposomes prepared by commercial phospholipids. Approximately 90% of liposome uptake could be inhibited by cytochalasin B and also by NaN3 and 2-deoxyglucose. This was consistent with the uptake being the result of endocytosis. The remaining uptake was probably the result of adhesion of liposomes to the cell membrane. The rate of efflux vs time of methotrexate entrapped in liposomes was much slower than that of free methotrexate which reinforces the concept that endocytosis is the main mode of liposomes uptake by the cells. Liposomes containing methotrexate at concentrations as low as 4.5 microM effectively inhibited the activity of dihydrofolate reductase which was used as a function parameter in this study. Similar inhibition of the enzyme activity by free methotrexate was achieved only at concentrations as high as 880 microM. The influence of liposomes lipid composition on the targeting of liposomes to Tetrahymena pyriformis cells was discussed.